Prof. Wang Liqiu reveals the mechanism of bio-inspired control of liquid flow published in Science Journal

The more we discover about the natural world, the more we find that nature is the greatest engineer. Past research believed that liquids can only be transported in fixed direction on species with specific liquid communication properties and cannot switch the transport direction. Recently, The Hong Kong Polytechnic University (PolyU) researchers have shown that an African plant controls water movement in a previously unknown way – and this could inspire breakthroughs in a range of technologies in fluid dynamics and nature-inspired materials, including applications that require multistep and repeated reactions, such as microassays, medical diagnosis and solar desalination etc. The study has been recently published in the international academic journal Science. Liquid transport is an unsung miracle of nature. Tall trees, for example, have to lift huge amounts of water every day from their roots to their highest leaves, which they accomplish in perfect silence. Some lizards and plants channel water through capillaries. In the desert, where making the most of scarce moisture is vital, some beetles can capture fog-borne water and direct it along their backs using a chemical gradient. Scientists have long sought to hone humankind’s ability to move liquids directionally. Applications as diverse as microfluidics, water harvesting, and heat transfer depend on the efficient directional transport of water, or other fluids, at small or large scales. While the above species provide nature-based inspiration, they are limited to moving liquids in a single direction. A research team led by Prof. WANG Liqiu, Otto Poon Charitable Foundation Professor in Smart and Sustainable Energy, Chair Professor of Thermal-Fluid and Energy Engineering, Department of Mechanical Engineering of PolyU, has discovered that the succulent plant Crassula muscosa, native to Namibia and South Africa, can transport liquid in selected directions. Together with colleagues from the University of Hong Kong and Shandong University, the PolyU researchers noticed that when two separate shoots of the plant were infused with the same liquids, the liquids were transported in opposite directions. In one case, the liquid travelled exclusively towards the tip, whereas the other shoot directed the flow straight to the plant root. Given the arid but foggy conditions in which C. muscosa lives, the ability to trap water and transport it in selected directions is a lifeline for the plant. As the shoots were held horizontally, gravity can be ruled out as the cause of the selective direction of transport. Instead, the plant’s special properties stem from the tiny leaves packed onto its shoots. Also known as “fins”, they have a unique profile, with a swept-back body (resembling a shark’s fin) tapering to a narrow ending that points to the tip of the plant. The asymmetry of this shape is the secret to C. muscosa’s selective directional liquid transport. It all has to do with manipulating the meniscus – the curved surface on top of a liquid. Specifically, the key lies in subtle differences between the fin shapes on different shoots. When the rows of fins bend sharply towards the tip, the liquid on the shoot also flows in that direction. However, on a shoot whose fins – although still pointing at the tip – have a more upward profile, the direction of movement is instead to the root. The flow direction depends on the angles between the shoot body and the two sides of the fin, as these control the forces exerted on droplets by the meniscus – blocking flow in one direction and sending it in the other. Armed with this understanding of how the plant directs liquid flow, the team created an artificial mimic. Dubbed CMIAs, for ‘C. muscosa-inspired arrays’, these 3D-printed fins act like the tilted leaves of C. muscosa, controlling the orientation of liquid flow. Cleverly, while the fins on a natural plant shoot are immobile, the use of a magnetic material for artificial CMIAs allows them to be reoriented at will. Simply by applying a magnetic field, the liquid flow through a CMIA can be reversed. This opens up the possibility of liquid transport along dynamically changing paths in industrial and laboratory settings. Alternatively, flow could be redirected by changing the spacing between fins. Numerous areas of technology stand to benefit from CMIAs. Prof. Wang said, “There are foresee applications of real-time directional control of fluid flow in microfluidics, chemical synthesis, and biomedical diagnostics. The biology-mimicking CMIA design could also be used not just for transporting liquids but for mixing them, for example in a T-shaped valve. The method is suited to a range of chemicals and overcomes the heating problem found in some other microfluidic technologies.”

Success in securing GRF/ECS 2024/25

In the 2024/25 results of grants from the Research Grants Council’s General Research Fund (GRF) and Early Career Scheme (ECS) announced in June 2024, ME’s success rate was 24% in 2024/25 exercise.  Six of our GRF/ECS proposals were funded. Congratulations to the following colleagues who were successful in securing a GRF/ECS grant in this round. Principal Investigator Co-Investigator  Project Title  Dr An Liang  Prof. Ni Meng (BRE)  Bubble dynamics and mass transport in anion exchange membrane water electrolysis cells for green hydrogen production  Dr Jiao Zengbao Dr Zheng Guangping (ME)  Atomic-scale structure, intrinsic properties, and deformation mechanisms of high-interstitial multicomponent intermetallic alloys with high strength and ductility  Dr Leung Chi Kin Randolph  Prof. Tang Shiu Keung (University of Hull, UK)  Establishment of Aeroacoustics of Distributed Surface Compliance for Broadband Reactive Liner Exposed to Subsonic Grazing Flow  Dr Navarro Alarcon David Prof. Yang Chenguang (University of the West of England Bristol)  Collective Dexterity to Shape and Transport Heterogeneous Aggregates by Multi-Robot Systems  Prof. Wang Zuankai Nil  Self-jumping of freezing droplets  Dr Zhang Xiao  Nil Modulating the Acidic Interface for Efficient Hydrogen Peroxide Production in a PEM Electrolyzer 

Prof. Wang Zuankai bestowed Nukiyama Memorial Award for exceptional thermal science and engineering research

Prof. WANG Zuankai, Associate Vice President (Research and Innovation), Kuok Group Professor in Nature-Inspired Engineering and Chair Professor of Nature-Inspired Engineering of the Hong Kong Polytechnic University (PolyU) has been bestowed the 2024 Nukiyama Memorial Award by the Heat Transfer Society of Japan for his significant contributions to thermal science and engineering.  The Nukiyama Memorial Award is presented biennially to a distinguished scientist in the field of thermal science and engineering. Prof. WANG has received this honour for his groundbreaking discovery in heat transfer research, which addresses critical scientific questions and tackles enduring technological challenges related to boiling phenomena.  Prof. WANG said, “I am very honored to receive this prestigious award in 2024, after 90 years’ publication of Prof. Nukiyama’s epoch-making work on boiling phenomena. His beautiful boiling curve, known as the Nukiyama Curve, has clarified the physics of boiling phenomena and has become a landmark in heat transfer textbooks today. Our work has fundamentally inhibited the centuries-old Leidenfrost effect, enabling a shift in the Nukiyama Curve and facilitating more efficient boiling heat transfer. These advancements hold immense potential for unlocking a wide array of applications.”  Prof. WANG’s innovation on structured thermal amour (STA) tackled the longstanding challenges posed by the Leidenfrost effect since 1756. His research “Inhibiting the Leidenfrost effect above 1,000°C for sustained thermal cooling,” published in Nature in 2022.  When the temperature exceeds the Leidenfrost point, a continuous vapour layer forms between the solid and the liquid, leading to a reduction in heat transfer due to increased thermal resistance. Finding an efficient method to cool hot surface has been a persistent challenge in the fields of thermal engineering and materials science.  Prof. WANG’s innovated STA strategy holds the potential to enable efficient liquid cooling at extremely high temperature, particularly in fields like aero-engines, space-engines and next generation nuclear reactors. This breakthrough also applies to electronics cooling which suffers from increased heat flux due to device miniaturization. The invention pushes the boundaries of liquid cooling up to over 1,000°C, resulting in significant technological advancements that enhance thermal cooling in nuclear power plants, engines, microelectronic chips and electronics devices. The Nukiyama Memorial Award was established by the Heat Transfer Society of Japan to commemorate remarkable contributions of Prof. Shiro Nukiyama as an outstanding heat transfer scientist. The Society aims to foster scientific and technical communication among researchers from various disciplines including mechanical engineering, chemical engineering, and nuclear engineering, among others.    

ME & AP Student Team Wins IMechE Best Student Design Award 2023/2024

The PolyU Undergraduate ME & AP Student Team won the Best Student Design Award 2023/2024 organized by the IMechE Hong Kong Branch. The team members are Gong Ziqi from the Department of Mechanical Engineering and Zhu Wenjia from the Department of Applied Physics. The winning project is called the "Wave Pillow". Nowadays, with the increase in the number of people suffering from cervical spondylosis, the need for treatment and corrective ergonomics has raised awareness among people and the medical community. There is a strong relationship between the quality of sleep and the incidence of whiplash. A proper pillow plays a crucial role in improving sleep quality. Therefore, this project design incorporates flexible electronic devices and various physical sensors to create smart, wave-shaped pillows that can be applied to different sleeping postures and accommodate people of different genders and ages. The design project was developed from multiple perspectives: Background, Design Concept, Mechanical Element, Innovation Achievement, and Commercial Viability, which comprehensively demonstrated the innovative and implementable nature of the design. The IMechE Hong Kong Branch organizes the annual Best Student Design Award to recognize the contributions to the mechanical industry from student design projects and to appreciate the performance of outstanding mechanical engineering students. The award is given to the design project that has the potential to impact the mechanical engineering industry, exhibits technical excellence in the field of mechanical engineering, demonstrates innovation, and shows commercial viability.

ME received 3 accolades at 49th International Exhibition of Inventions Geneva

Impactful innovations from The Hong Kong Polytechnic University (PolyU) won a record-breaking number of accolades at the 49th International Exhibition of Inventions Geneva (Geneva Inventions Expo), a widely recognised annual event devoted exclusively to invention. The Department is pleased to have three innovations seized two Silver Medals and one Bronze Medal. This achievement underscores the commitment of the ME community, encompassing scholar, student and alumnus, to embracing research breakthroughs.   Silver Medal .color-button { background-color: #C0c0c0; color: white; transition: background-color 0.3s; transform: skew(-30deg); } .text_format { display: inline-block; transform: skew(30deg); } .color-button2 { background-color: #CD7F32; color: white; transition: background-color 0.3s; transform: skew(-30deg); } Smart Headset featuring Adaptive Noise Filters for Individuals with Autism Spectrum Disorder Principle Investigator: Dr CHOY Yat Sze Associate Professor, Department of Mechanical Engineering Project description: This innovative smart headset creates a personalised adaptive noise filter for users with Autism Spectrum Disorder (ASD). The noise filter is based on the unique aural perception response of each user, reducing irritating noise without interfering with normal everyday sounds such as speech. This makes the sound perceived by the user more comfortable, helping alleviate negative behaviour triggered by intolerable sound stimuli. The smart headset works with a mobile application that quickly assesses the aural perception response of each user and creates a unique noise filter. The smart headset is a significant technological breakthrough that could transform the lives of individuals with ASD by making their daily experiences more manageable and enjoyable. It also enhances their communication, education, and social lives. It benefits both the users and their families by improving their quality of life. Silver Medal ZC-01 Automatic Washroom Cleaning Robot Principle Investigator: Mr LEE Tsz Chung Curry MSc in ME Graduate, Department of Mechanical Engineering Founder, ZeeqClean Technology Limited (a PolyU start-up) Project description: The ZC-01™ is a commercial toilet cleaning robot that operates either manually or automatically. It uses non-visual LiDAR and infrared sensors for adaptive cruise, and can clean toilets and urinals in a contactless way, with drying and UV sterilisation functions. Before cleaning, the ZC-01™ can detect and open the toilet lid. The ZC-01™ can reduce the cost of commercial cleaning and help industry become more environmentally-friendly by recording energy and chemical consumption. Most importantly, ZC-01™ can reduce work aversion in commercial washroom cleaning. The target market of the ZC-01™ is Hong Kong's commercial buildings, government buildings, large public toilets, international airport, and its international conference venue AsiaWorld-Expo, as well as large highway rest areas in the Mainland – all places that require a large amount of cleaning. Bronze Medal Thick Glassy Carbon Manufacturing and Physical Property Adjustment through Heat Treatment Principle Investigator: Mr YANG Yi, PhD Student, Department of Mechanical Engineering Founder, Discarbonery Technology Limited (a PolyU start-up) Project description: Glassy carbon is a carbon material that does not form graphite crystals, and has excellent physical and chemical properties. It can be used in various applications such as glass moulding and the semiconductor industry. However, this material has a number of challenges – such as size limitations, high preparation costs, and high hardness – that make it difficult to process directly. To overcome these challenges, we have developed a way to produce large, cost-effective, shape-controlled glassy carbon products, and a way to use heat treatment to subsequently adjust their physical properties. These strategies enable us to fine-tune the properties of glassy carbon to suit different applications and extend product lifespan.

ME surges in Quacquarelli Symonds (QS) World University Rankings by Subject 2024

In the latest Quacquarelli Symonds (QS) World University Rankings by Subject 2024 released on 10 April 2024, The Hong Kong Polytechnic University (PolyU) has attained remarkable success, ranking within the top 20 globally for five subjects and the first in Hong Kong for four subjects. Several engineering and technology-related fields also placed in the top 100 worldwide. We are very pleased to see that PolyU’s Mechanical Engineering subject has surged from 120th to 73rd. The QS World University Rankings by Subject evaluated institutions across 54 subjects in five broad subject areas. The subject rankings are weighted based on academic reputation, employer reputation, research citations per paper, the H-index and international research network.  The Department will refer to the rankings and other assessments to strive for improvement and lead ME to a new horizon. Our Performance in Key Rank League Tables .color-button { background-color: #A02337; color: white; transition: background-color 0.3s; } .color-button:hover { background-color: white; color: #A02337; }  

2 ME Scholars recognised amongst world’s most highly cited researchers 2023

Congratulations to Prof. WANG Zuankai and Dr ZHANG Xiao being two of the 15 PolyU academics who have been recognised in the "Highly Cited Researchers 2023" list by Clarivate Analytics. The Hong Kong Polytechnic University (PolyU) and Clarivate Plc (Clarivate) jointly hosted the “2023 Highly Cited Researchers Awards Ceremony” on 15 March 2024. Officiated by PolyU Vice President (Research and Innovation), Prof. Christopher CHAO, and Clarivate™ Vice President for Asia Pacific (Academia and Government), Mr Osher GILINSKY, the Ceremony recognised PolyU academics who have been named as Highly Cited Researchers™ in 2023, the significant impact of their research and the positive contributions they have made in their field. A total of 6,849 researchers from 67 countries and regions from a diverse range of research fields were named as Highly Cited Researchers 2023. The most influential scholars from around the world have been identified, determined by the production of multiple highly cited papers that rank in the top 1% by citations for field and year in the Web of Science™ over the last 11 years. The inclusion of PolyU academics in this list is testament to the University’s pursuit of research excellence. In the last year, PolyU had the third highest number of the world’s most Highly Cited Researchers in Hong Kong, including ten awardees in cross-field research, two from engineering disciplines, and one from chemistry, computer science and the social sciences respectively. The department is proud of Prof. Wang and Dr Zhang’s outstanding achievements in ground-breaking research. Their accomplishments reaffirm ME’s dedication to research excellence.  

Joint School Sharing Forum: Exploring the Role of Mechanical Engineers

On February 22, 2024, the Caritas School Social Work Service and the PolyU Department of Mechanical Engineering joined forces to organize a school visit and a joint school sharing forum at Tuen Mun Catholic Secondary School. We were delighted to spend an afternoon engaging with the principal, vice principal, teachers, and students, learning about their studies and aspirations. The joint school sharing forum welcomed approximately 150 Form 5 students from Pope Paul VI College and Tuen Mun Catholic Secondary School. We extend our gratitude to our esteemed industrial partner, REC Engineering Co. Ltd., for their enthusiastic support. Ir Antonio Chan, the Deputy Managing Director, played a pivotal role in facilitating the collaboration between Caritas and the Department. The forum commenced with Antonio's insightful discussion on the practical needs of the workplace. Subsequently, the Caritas School Social Work Service hosted an interactive quiz game, where students eagerly sought answers to general engineering questions. Next, our Department Head, Prof. Su Zhongqing, provided an in-depth explanation of the research areas and modern applications of mechanical engineering. Following Prof. Su's presentation, student and graduate representatives shared their personal experiences in both studying and working in the field. Mr Jeffrey KIM Jaeyoun, a Year 4 student pursuing a BEng (Hons) in Mechanical Engineering, captivated the audience with his account of the wonderful experiences gained from the PolyU E-Formula Racing Team's involvement in Formula One races. Additionally, Mr Adrian WU, a 2018 graduate of the BEng (Hons) in Product Analysis and Engineering Design programme, currently serves as a Product Manager in Asia Pacific at BELIMO Asia Pacific Limited. He shed light on how his work directly impacts everyone's lives. Following the sharing sessions, Dr Henry Chu, the Scheme Leader of the BEng (Hons) Scheme in Mechanical Engineering, invited students to explore the study of mechanical engineering at PolyU. He specifically highlighted the new Intelligent Robotics Engineering programme and the recently established DSE Entry Scholarship. The event concluded with an open forum, chaired by Dr Tracy Choy, the Chairlady of the Publicity Committee, accompanied by Dr Chu, Jeffrey, and Adrian. During this session, students posed thoughtful questions to gain a better understanding of the engineering industry and to prepare for their personal development. To further enrich the visit, the ME delegation explored the school's workshop, gaining insights into the students' design and engineering projects. This visit proved to be highly fruitful, deepening mutual understanding and providing students with first-hand information to guide them in their future studies and career choices. Overall, the Joint School Sharing Forum proved to be an invaluable opportunity for students to explore the multifaceted world of mechanical engineering, empowering them to make informed decisions about their academic and professional paths.  

ME Undergraduate receives the Best URIS Research Project Award 2023

Congratulations to our undergraduate, Mr HE Zhengyang, on receiving the Grand Award in the Best URIS Research Project Award 2023. Under the supervision of Dr TANG Hui, Associate Professor of ME, Mr HE has demonstrated distinctive research achievements through his project which contributed to harvesting energy from flowing water with a unique flapping-foil-based hydropower harvester. This award also symbolises the recognition of his endeavour to advance knowledge with applications.   Grand Award Project Title: Development of a New Generation of Flow Energy Harvester Awardee: HE Zhengyang, BEng (Hons) in Mechanical Engineering Chief Supervisor: Dr Tang Hui, Department of Mechanical Engineering Abstract: The URIS project achieved a breakthrough in harvesting energy from flowing water with a unique flapping-foil-based hydropower harvester. Unlike traditional turbine-based technologies, this harvester brings several advantages, such as lower cut-in speeds, slower tip speeds, better-filling factors, and scalability. To convert water flow into electricity, a hybrid power-take-off unit combining triboelectricity and electromagnetic induction was designed, developed, and tested. Through extensive water-tunnel experiments, the unit was optimized for different water speeds and foil movements. The flapping-foil technology operates at lower tip speeds, making it environmentally friendly for energy harvesting in rivers and oceans. Its applications also include charging low-power devices and measuring water speed simultaneously, especially in remote off-grid areas. This innovation opens up new possibilities for harnessing renewable energy from water sources and providing sustainable power solutions in various settings. The Undergraduate Research and Innovation Scheme (URIS) is a prestigious programme of PolyU to promote undergraduate research with the aim to nurture the next generation of intellectuals. The programme offers an enquiry-based learning opportunity to empower PolyU Ug students to build research track records, establish research networks, gain exposure to their fields of study and equip themselves with competencies to take up research career opportunities in Hong Kong and beyond. It is great to see the undergraduate from the Department being acclaimed for his research innovation.

ME Staff Honoured for 2023 Long Service Award

Colleagues of the PolyU Department of Mechanical Engineering (ME) have always been devoting themselves to the development of ME. This year, the Department Head Prof. Su Zhongqing, on behalf of the University, paid tribute to long-serving staff members for their loyal and committed service over the years. Congratulations to the awardees and heartfelt thanks for their years of dedication and devotion which have marked the achievements of the Department.   Long Service Award 2023 Award Recipients Length of Service Name  Post Title  30 years Ms Packy Chan  陳碧琪  Clerical Officer II 15 years Ms Joanne Cheng  鄭詩婷 Executive Officer 5 years  Mr Billy Yan  甄超恒  Assistant Technical Officer